DOCSLIB.ORG

PETROLEUM ENGINEERING NEWSLETTER Is Theestablishmentof$3.5Millionf.H

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
PETROLEUM ENGINEERING NEWSLETTER Is Theestablishmentof$3.5Millionf.H VOL. 17, NO. 1 SEPTEMBER 2013 The Change Continues... Merelli/Cimerax Energy Distinguished Department Head Chair in Petroleum Engineering. Many thanks to Cimarex for the commitment to the Colorado School of Mines, in honor of Mick, a founder of Cimarex and a shining example of what a Miner can be. The next step is to bring this to the attention of those with the combination of leadership, management skills and burning love for the education of the future of the petroleum industry. Please respond to this call to CSM PE alumni to think about this challenge themselves, or bring this to the attention of someone you would entrust with our department and your sons and daughters. The ad will soon be out. Dr. Fleckenstein with Dr. Waleed Abass and a friend. I’m happy to report that the PE Department passed the ABET review process with flying colors. This is a critical objective Greetings from Golden. The Petroleum Engineering for us, and as the result of the efforts of our faculty and staff, Department has continued to evolve and change as we are accredited for the full 6 years. it settles into Marquez Hall. There have only been two permanent Department Heads since 1980, Dr. Craig Van Kirk and Dr. Ramona Graves. I’ve committed to staying in the position on an interim basis until we find a leader of comparable quality to my predecessors, and one must be careful of one’s commitments, because those two are irreplaceable. I am discovering on a firsthand basis what a tremendous job that both Craig and Ramona have done, and just what the responsibilities and rewards are possible in this job. The first step to attracting the world class leader this job demands is the establishment of the $3.5 million F.H. “Mick” Ramona and Will in Kuwait. The first year is behind us after the move to Marquez Hall, and it has fulfilled its promise to be the best possible PE STATISTICS FOR 12-13 facility for Petroleum Engineering in the world. The only possible exception being the fact that it was designed for New Research a department about half the size that demand had driven Contracts $5,862,839 our growth in students and research to. If you would like to donate a building to allow us to accommodate that growth, GRADUATES please contact President Scoggins or myself and we will be PhD 3 glad to talk with you about that. Seriously (no, we really MS/ME 20 could use the donation), the building that our alumni and BS 130 industry partners made possible has been wonderful, and Placement as of May (%) 96% everyone that donated to this endeavor can be very proud. The Petroleum Department enjoys a special relationship with CURRENT ENROLLMENT our alumni and industry partners and supporters that is the PhD 49 envy of the campus. I cannot express how important that MS/ME 72 relationship is, both financially to us from the continual flow of Seniors 170 donations to support our department efforts, but also the help Juniors 205 with intangible things, like assistance with our field sessions, PETROLEUM ENGINEERING NEWSLETTER *Sophomore/Freshmen - do not declare until Spring Semester DR. FLECKENSTEIN CONT. or a willingness to serve on our various steering committees. and do many other things. In light of Craig’s service over Many thanks. those 35 years, I hope that he greatly enjoys his time away, and will continue to assist us over the coming many years. Since Marquez Hall is the newest and most beautiful building The department owes a debt of gratitude to Craig for all that on campus, I believe it is the flagship of the CERSE college he has done. and its six departments. Dr. Graves, as the Dean, is effectively our Admiral (Queen?), and so I offered to convert a beautiful Tom Bratton has completed the first year of Schlumberger’s space that Bud and Kaye Isaacs donated to an office for Dean commitment to support our department and that is going Graves, in her flagship building, which the Isaacs agreed extremely well. Tom has been instrumental in assisting with our to. The construction of the Dean’s office is almost completed, research and graduate needs, and is teaching with Dr. Manika and it is, like everything else in our new home, spectacular. Prasad our undergraduate formation evaluation class. He It seemed fitting to me that the person most responsible for also will be instrumental in working with Petroleum, Geology putting Marquez Hall together in its final form should be and Geophysics to help address their graduate formation based there, and I am glad that my offer was accepted. evaluation needs as well. Not to be left out, Halliburton is greatly increasing their technology commitment to the Halliburton Visualization Center, and is also supporting a graduate fellows program, with six fellows from various departments around campus. These Fellows, plus new graduate students and research faculty, will be housed in space converted and remodeled in the Green Center for us. This space, outside Marquez Hall, emphasizes the multi-disciplinary nature of our research, and is also necessitated because we are essentially out of room Coiled Tubing Drilling Rig – Kuparuk, Alaska. in Marquez Hall for additional faculty, or We have two new faculty that have joined us. Dr. Ronny graduate students. Pini joins us from Stanford University, where he completed his postdoctoral work. Dr. Pini is an experimentalist whose The students and faculty, primary work has been in the areas of CO2 sequestration as you will read in and coal bed methane. Dr. Pini fills an immediate void in the this newletter, have PE undergraduate laboratory classes left by the promotion accomplished many of Dr. Ramona Graves to the Deanship of CERSE. He has wonderful things this collaborated with both national and international institutions Hydraulic Fracturing meets the White House. year – starting with and organizations and has an impressive array of publications. winning the Petro-Bowl His research interests are adsorption mechanisms in CBM, at the SPE-ATCE. This year we had approximately 200 students something easily translated to other unconventional resources, divided into 4 PEGN 315 field sessions that went to Alaska, such as shales. California, Gulf Coast and Wyoming. I accompanied the group that went to Alaska, and was very impressed with the level Dr. Luis Zerpa, joins us after completing his doctoral work at of presentations and visits arranged by our host companies, CSM in Petroleum Engineering in deepwater flow assurance, and a special shout out to ConocoPhillips, who chartered a with close collaboration with the CSM Center for Hydrate plane and took the whole group to the North Slope to tour the Research. Dr. Zerpa taught for five years at the University of Kuparak field. The field sessions went extremely well, and really Zulia in Venezuela at the Masters level, and brings a South introduced the students just beginning the Petroleum classes to American perspective to our staff. Dr. Zerpa is teaching this the breadth and depth of the oil and gas industry. On behalf of fall PEGN 423, our Reservoir Engineering I class that has the department, many thanks to all who assisted us. long been the domain of Dr. Van Kirk (can anyone say Tarner Project?). The Petroleum Department was honored to be asked to assist in an effort to design a new research facility in Kuwait. Dr. Van Kirk is now entering a new period in his relationship This is a multi-year effort, which is evolving as the process with CSM as his transitional retirement period ends, and Craig continues. Dr. Graves and I spent three weeks in Kuwait this expressed the desire to me to take only his second sabbatical summer conducting a series of workshops, to help identify in 35 years at Mines to spend more time with his grandkids and prioritize challenges meaningful to the various parts of 2 DR. FLECKENSTEIN CONT. the Kuwaiti oil industry. Dr. Hossein Kazemi participated in 3 4. evaluate the procedures employed by various days of the workshops, and made several presentations that operators and service companies for “green” illustrated the effect that good research, coupled with well- versus “non-green” well completions designed pilot programs, can have on the success of large I am also working on the commercialization of several investments by both international and national oil companies. technologies either directly through CSM, or through a This effort is off to a flying start with our partners, and related start-up called FracOptimal LLC, which had a very reaffirms the CSM PE Department’s standing as a leader in important milestone of revenue generation through its first both petroleum engineering research and education. generation of multistage fracturing technology, and is now working through its second generation. CSM is applying for Patent protection for a casing seal verification technology I developed to positively prove hydraulic isolation exists in the annulus of casing. I am also negotiating with several investments groups to complete the research on a propping technology for fractured completions. Kuwait City at night. I personally have continued working on a series of high-level unconventional resource development workshops in Eastern Europe with the latest in three cities in the Ukraine, and another in Lithuania. These workshops present an unbiased Dr. Ramona Graves, Dr. Waleed Abass and Dr. Will Fleckenstein in front of the view of the issues associated with shale development, and iconic water towers in Kuwait. discuss the North American experience, with the technology, regulatory frameworks, economic benefits, and impacts on The changes continue in the PE Department. This is probably infrastructure, environment and society in general.
Load more

Recommended publications
  • Coal and Oil: the Dark Monarchs of Global Energy – Understanding Supply and Extraction Patterns and Their Importance for Futur
    nam et ipsa scientia potestas est List of Papers This thesis is based on the following papers, which are referred to in the text by their Roman numerals. I Höök, M., Aleklett, K. (2008) A decline rate study of Norwe- gian oil production. Energy Policy, 36(11):4262–4271 II Höök, M., Söderbergh, B., Jakobsson, K., Aleklett, K. (2009) The evolution of giant oil field production behaviour. Natural Resources Research, 18(1):39–56 III Höök, M., Hirsch, R., Aleklett, K. (2009) Giant oil field decline rates and their influence on world oil production. Energy Pol- icy, 37(6):2262–2272 IV Jakobsson, K., Söderbergh, B., Höök, M., Aleklett, K. (2009) How reasonable are oil production scenarios from public agen- cies? Energy Policy, 37(11):4809–4818 V Höök M, Söderbergh, B., Aleklett, K. (2009) Future Danish oil and gas export. Energy, 34(11):1826–1834 VI Aleklett K., Höök, M., Jakobsson, K., Lardelli, M., Snowden, S., Söderbergh, B. (2010) The Peak of the Oil Age - analyzing the world oil production Reference Scenario in World Energy Outlook 2008. Energy Policy, 38(3):1398–1414 VII Höök M, Tang, X., Pang, X., Aleklett K. (2010) Development journey and outlook for the Chinese giant oilfields. Petroleum Development and Exploration, 37(2):237–249 VIII Höök, M., Aleklett, K. (2009) Historical trends in American coal production and a possible future outlook. International Journal of Coal Geology, 78(3):201–216 IX Höök, M., Aleklett, K. (2010) Trends in U.S. recoverable coal supply estimates and future production outlooks. Natural Re- sources Research, 19(3):189–208 X Höök, M., Zittel, W., Schindler, J., Aleklett, K.
    [Show full text]
  • Statoil ASA Statoil Petroleum AS
    Offering Circular A9.4.1.1 Statoil ASA (incorporated with limited liability in the Kingdom of Norway) Notes issued under the programme may be unconditionally and irrevocably guaranteed by Statoil Petroleum AS (incorporated with limited liability in the Kingdom of Norway) €20,000,000,000 Euro Medium Term Note Programme On 21 March 1997, Statoil ASA (the Issuer) entered into a Euro Medium Term Note Programme (the Programme) and issued an Offering Circular on that date describing the Programme. The Programme has been subsequently amended and updated. This Offering Circular supersedes any previous dated offering circulars. Any Notes (as defined below) issued under the Programme on or after the date of this Offering Circular are issued subject to the provisions described herein. This does not affect any Notes issued prior to the date hereof. Under this Programme, Statoil ASA may from time to time issue notes (the Notes) denominated in any currency agreed between the Issuer and the relevant Dealer (as defined below). The Notes may be issued in bearer form or in uncertificated book entry form (VPS Notes) settled through the Norwegian Central Securities Depositary, Verdipapirsentralen ASA (the VPS). The maximum aggregate nominal amount of all Notes from time to time outstanding will not exceed €20,000,000,000 (or its equivalent in other currencies calculated as described herein). The payments of all amounts due in respect of the Notes issued by the Issuer may be unconditionally and irrevocably guaranteed by Statoil A6.1 Petroleum AS (the Guarantor). The Notes may be issued on a continuing basis to one or more of the Dealers specified on page 6 and any additional Dealer appointed under the Programme from time to time, which appointment may be for a specific issue or on an ongoing basis (each a Dealer and together the Dealers).
    [Show full text]
  • Deep Borehole Placement of Radioactive Wastes a Feasibility Study
    DEEP BOREHOLE PLACEMENT OF RADIOACTIVE WASTES A FEASIBILITY STUDY Bernt S. Aadnøy & Maurice B. Dusseault Executive Summary Deep Borehole Placement (DBP) of modest amounts of high-level radioactive wastes from a research reactor is a viable option for Norway. The proposed approach is an array of large- diameter (600-750 mm) boreholes drilled at a slight inclination, 10° from vertical and outward from a central surface working site, to space 400-600 mm diameter waste canisters far apart to avoid any interactions such as significant thermal impacts on the rock mass. We believe a depth of 1 km, with waste canisters limited to the bottom 200-300 m, will provide adequate security and isolation indefinitely, provided the site is fully qualified and meets a set of geological and social criteria that will be more clearly defined during planning. The DBP design is flexible and modular: holes can be deeper, more or less widely spaced, at lesser inclinations, and so on. This modularity and flexibility allow the principles of Adaptive Management to be used throughout the site selection, development, and isolation process to achieve the desired goals. A DBP repository will be in a highly competent, low-porosity and low-permeability rock mass such as a granitoid body (crystalline rock), a dense non-reactive shale (chloritic or illitic), or a tight sandstone. The rock matrix should be close to impermeable, and the natural fractures and bedding planes tight and widely spaced. For boreholes, we recommend avoiding any substance of questionable long-term geochemical stability; hence, we recommend that surface casings (to 200 m) be reinforced polymer rather than steel, and that the casing is sustained in the rock mass with an agent other than standard cement.
    [Show full text]
  • Norwegian Petroleum Technology a Success Story ISBN 82-7719-051-4 Printing: 2005
    Norwegian Academy of Technological Sciences Offshore Media Group Norwegian Petroleum Technology A success story ISBN 82-7719-051-4 Printing: 2005 Publisher: Norwegian Academy of Technological Sciences (NTVA) in co-operation with Offshore Media Group and INTSOK. Editor: Helge Keilen Journalists: Åse Pauline Thirud Stein Arve Tjelta Webproducer: Erlend Keilen Graphic production: Merkur-Trykk AS Norwegian Academy of Technological Sciences (NTVA) is an independent academy. The objectives of the academy are to: – promote research, education and development within the technological and natural sciences – stimulate international co-operation within the fields of technology and related fields – promote understanding of technology and natural sciences among authorities and the public to the benefit of the Norwegian society and industrial progress in Norway. Offshore Media Group (OMG) is an independent publishing house specialising in oil and energy. OMG was established in 1982 and publishes the magazine Offshore & Energy, two daily news services (www.offshore.no and www.oilport.net) and arranges several petro- leum and energy based conferences. The entire content of this book can be downloaded from www.oilport.net. No part of this publication may be reproduced in any form, in electronic retrieval systems or otherwise, without the prior written permission of the publisher. Publisher address: NTVA Lerchendahl gaard, NO-7491 TRONDHEIM, Norway. Tel: + (47) 73595463 Fax: + (47) 73590830 e-mail: [email protected] Front page illustration: FMC Technologies. Preface In many ways, the Norwegian petroleum industry is an eco- passing $ 160 billion, and political leaders in resource rich nomic and technological fairy tale. In the course of a little oil countries are looking to Norway for inspiration and more than 30 years Norway has developed a petroleum guidance.
    [Show full text]
  • Petroleum Engineering (PETE) | 1
    Petroleum Engineering (PETE) | 1 PETE 3307 Reservoir Engineering I PETROLEUM ENGINEERING Fundamental properties of reservoir formations and fluids including reservoir volumetric, reservoir statics and dynamics. Analysis of Darcy's (PETE) law and the mechanics of single and multiphase fluid flow through reservoir rock, capillary phenomena, material balance, and reservoir drive PETE 3101 Drilling Engineering I Lab mechanisms. Preparation, testing and control of rotary drilling fluid systems. API Prerequisites: PETE 3310 and PETE 3311 recommended diagnostic testing of drilling fluids for measuring the PETE 3310 Res Rock & Fluid Properties physical properties of drilling fluids, cements and additives. A laboratory Introduction to basic reservoir rock and fluid properties and the study of the functions and applications of drilling and well completion interaction between rocks and fluids in a reservoir. The course is divided fluids. Learning the rig floor simulator for drilling operations that virtually into three sections: rock properties, rock and fluid properties (interaction resembles the drilling and well control exercises. between rock and fluids), and fluid properties. The rock properties Corequisites: PETE 3301 introduce the concepts of, Lithology of Reservoirs, Porosity and PETE 3110 Res Rock & Fluid Propert Lab Permeability of Rocks, Darcy's Law, and Distribution of Rock Properties. Experimental study of oil reservoir rocks and fluids and their interrelation While the Rock and Fluid Properties Section covers the concepts of, applied
    [Show full text]
  • Annual Report 2019 the 2019 Partners
    THE NATIONAL IOR CENTRE OF NORWAY Annual report 2019 The 2019 partners ConocoPhillips Observers Contents Management Team 4 Board Members 4 Technical Committee 5 Scientific Advisory Committee 5 About 6 Research Themes 7 Greetings from the Director 8 Greetings from the Chairman of the Board 9 Consortium Partners 10 Activity Highlights On the use of thermo-thickening polymers for in-depth mobility control – large scale testing 12 Developing the ensemble Kalman filter based approach for history matching 15 Coordinating Upscaling Workflow 16 Interpore – 3rd National Workshop on Porous Media 17 New management team 18 Great expectations from the Research Council of Norway 19 Researcher Profiles Mehul Vora 20 André Luís Morosov 21 Micheal Oguntola 21 Tine Vigdel Bredal 22 Arun Selvam 22 Panagiotis Aslanidis 23 William Chalub Cruz 23 Nisar Ahmed 24 Aleksandr Mamonov 24 Juan Michael Sargado 25 Runar Berge 25 Highlights from the PhD Defences PhD Defences 2019 26 Core scale modelling of EOR transport mechanisms 27 Smart Water for EOR from Seawater and Produced Water by Membranes 27 Wettability estimation by oil adsorption 28 CO2 Mobility Control with Foam for EOR and Associated Storage 28 Interaction between two calcite surfaces in aqueous solutions … 29 Research Dissemination, Conferences & Awards Lundin Norway shares all data from one field 30 PhD student Mehul Vora presented at OG21 31 Selected Papers 32 Media Contributions 2019 35 Who are we? 36 Publications 37 3 Management Team Ying Guo Tina Puntervold Randi Valestrand Centre Director Assistant
    [Show full text]
  • New Petrophysical Magnetic Methods MACC and MAFM in Permeability
    Geophysical Research Abstracts Vol. 14, EGU2012-13161, 2012 EGU General Assembly 2012 © Author(s) 2012 New petrophysical magnetic methods MACC and MAFM in permeability characterisation of petroleum reservoir rock cleaning, flooding modelling and determination of fines migration in formation damage O. P. Ivakhnenko Department of Petroleum Engineering, Kazakh-British Technical University, 59 Tolebi Str. Almaty, Kazakhstan ([email protected]; [email protected]/Fax: +7 727 2720487) Potential applications of magnetic techniques and methods in petroleum engineering and petrophysics (Ivakhnenko, 1999, 2006; Ivakhnenko & Potter, 2004) reveal their vast advantages for the petroleum reser- voir characterisation and formation evaluation. In this work author proposes for the first time developed systematic methods of the Magnetic Analysis of Core Cleaning (MACC) and Magnetic Analysis of Fines Migration (MAFM) for characterisation of reservoir core cleaning and modelling estimations of fines migration for the petroleum reservoir formations. Using example of the one oil field we demonstrate results in application of these methods on the reservoir samples. Petroleum reservoir cores samples have been collected within reservoir using routine technique of reservoir sampling and preservation for PVT analysis. Immediately before the MACC and MAFM studies samples have been exposed to atmospheric air for a few days. The selected samples have been in detailed way characterised after fluid cleaning and core flooding by their mineralogical compositions and petrophysical parameters. Mineralogical composition has been estimated utilizing XRD techniques. The petrophysical parameters, such as permeability and porosity have been measured on the basis of total core analysis. The results demonstrate effectiveness and importance of the MACC and MAFM methods for the routine core analysis (RCAL) and the special core analysis (SCAL) in the reservoir characterisation, core flooding and formation damage analysis.
    [Show full text]
  • Applied Earth Sciences Natural Resources from the Earth, Ranging from Engineers Know Where Those Resources Can Be Found Raw Materials to Energy
    complement your academic studies, you will have the opportunity to work intensively with TU Delft’s partners in industry. For example, TU Delft is a participant in ISAPP (Integrated System Approach Petroleum Production), a large collaborative project involving TU Delft, Shell and TNO established for the purpose of boosting oil production by improving the flow of oil and water in oil reservoirs, and CATO, a consortium doing research on the collection, transport and storage of CO2. Managing the Earth’s resources for today and tomorrow Programme tracks • Petroleum Engineering and Geosciences covers both the technologies involved in extracting petroleum from the Earth, and the tools for assessing hydrocarbon reservoirs to gain an MSc Programme understanding of their potential. The track is divided into two specialisations: Petroleum Engineering covers all upstream Applied Earth aspects from reservoir description and drilling techniques to field management and project Sciences economics. Reservoir Geology covers the use of modern measurement and computational methods to obtain a quantitative understanding of hydrocarbon reservoirs. • Applied Geophysics is a joint degree track offered collaboratively by TU Delft, ETH Zürich and RWTH Aachen University. It trains students in geophysical aspects of environmental and engineering studies and in the exploration, exploitation and management of hydrocarbon and geothermal energy. Disciplines covered include acoustic and electromagnetic wave theory, seismic data acquisition, imaging and interpretation, borehole logging, rock-fluid interaction and petroleum geology. Everything we build and use on the surface of our • Resource Engineering covers the extraction of planet comes from the Earth. Applied Earth Sciences natural resources from the Earth, ranging from engineers know where those resources can be found raw materials to energy.
    [Show full text]
  • Best Research Support and Anti-Plagiarism Services and Training
    CleanScript Group – best research support and anti-plagiarism services and training List of oil field acronyms The oil and gas industry uses many jargons, acronyms and abbreviations. Obviously, this list is not anywhere near exhaustive or definitive, but this should be the most comprehensive list anywhere. Mostly coming from user contributions, it is contextual and is meant for indicative purposes only. It should not be relied upon for anything but general information. # 2D - Two dimensional (geophysics) 2P - Proved and Probable Reserves 3C - Three components seismic acquisition (x,y and z) 3D - Three dimensional (geophysics) 3DATW - 3 Dimension All The Way 3P - Proved, Probable and Possible Reserves 4D - Multiple Three dimensional's overlapping each other (geophysics) 7P - Prior Preparation and Precaution Prevents Piss Poor Performance, also Prior Proper Planning Prevents Piss Poor Performance A A&D - Acquisition & Divestment AADE - American Association of Drilling Engineers [1] AAPG - American Association of Petroleum Geologists[2] AAODC - American Association of Oilwell Drilling Contractors (obsolete; superseded by IADC) AAR - After Action Review (What went right/wrong, dif next time) AAV - Annulus Access Valve ABAN - Abandonment, (also as AB) ABCM - Activity Based Costing Model AbEx - Abandonment Expense ACHE - Air Cooled Heat Exchanger ACOU - Acoustic ACQ - Annual Contract Quantity (in reference to gas sales) ACQU - Acquisition Log ACV - Approved/Authorized Contract Value AD - Assistant Driller ADE - Asphaltene
    [Show full text]
  • Elasto-Plastic Deformation and Flow Analysis in Oil
    ELASTO-PLASTIC DEFORMATION AND FLOW ANALYSIS IN OIL SAND MASSES by THILLAIKANAGASABAI SRITHAR B. Sc (Engineering), University of Peradeniya, Sri Lanka, 1985 M. A. Sc. (Civil Engineering) University of British Columbia, 1989 A THESIS SUBMITTED IN PARTIAL FULFILLMENT OF THE REQUIREMENTS FOR THE DEGREE OF DOCTOR OF PHILOSOPHY in THE FACULTY OF GRADUATE STUDIES Department of CIVIL ENGINEERING We accept this thesis as conforming to the required standard THE UNIVERSITY OF BRITISH COLUMBIA April, 1994 © THILLAIKANAGASABAI SRITHAR, 1994 _______________________ In . presenting this thesis in partial fulfilment of the requirements for an advanced degree at the University of British Columbia, I agree that the Library shall make it freely available for reference and study. I further agree that permission for extensive copying of this thesis for scholarly purposes may be granted by the head of my department or by his or her representatives. It is understood that copying or publication of this thesis for financial gain shall not be allowed without my written permission. (Signature) Department of Civil Engineering The University of British Columbia Vancouver, Canada Date - A?R L 9 L DE-6 (2188) Abstract Prediction of stresses, deformations and fluid flow in oil sand layers are important in the design of an oil recovery process. In this study, an analytical formulation is developed to predict these responses, and implemented in both 2-dimensional and 3-dimensional finite element programs. Modelling of the deformation behaviour of the oil sand skeleton and modelling of the three-phase pore fluid behaviour are the key issues in developing the analytical procedure. The dilative nature of the dense oil sand matrix, stress paths that involve decrease in mean normal stress under constant shear stress, and loading-unloading sequences are some of the important aspects to be considered in modelling the stress-strain behaviour of the sand skeleton.
    [Show full text]
  • Techniques for Modeling Complex Reservoirs and Advanced Wells
    TECHNIQUES FOR MODELING COMPLEX RESERVOIRS AND ADVANCED WELLS A DISSERTATION SUBMITTED TO THE DEPARTMENT OF ENERGY RESOURCES ENGINEERING AND THE COMMITTEE ON GRADUATE STUDIES OF STANFORD UNIVERSITY IN PARTIAL FULFILLMENT OF THE REQUIREMENTS FOR THE DEGREE OF DOCTOR OF PHILOSOPHY Yuanlin Jiang December 2007 °c Copyright by Yuanlin Jiang 2008 All Rights Reserved ii I certify that I have read this dissertation and that, in my opinion, it is fully adequate in scope and quality as a dissertation for the degree of Doctor of Philosophy. Dr. Hamdi Tchelepi Principal Advisor I certify that I have read this dissertation and that, in my opinion, it is fully adequate in scope and quality as a dissertation for the degree of Doctor of Philosophy. Dr. Khalid Aziz Advisor I certify that I have read this dissertation and that, in my opinion, it is fully adequate in scope and quality as a dissertation for the degree of Doctor of Philosophy. Dr. Roland Horne Approved for the University Committee on Graduate Studies. iii Abstract The development of a general-purpose reservoir simulation framework for coupled systems of unstructured reservoir models and advanced wells is the subject of this dissertation. Stanford's General Purpose Research Simulator (GPRS) serves as the base for the new framework. In this work, we made signi¯cant contributions to GPRS, in terms of architectural design, extensibility, computational e±ciency, and new advanced well modeling capabilities. We designed and implemented a new architectural framework, in which the fa- cilities (man-made) model is treated as a separate component and promoted to the same level as the reservoir (natural) component.
    [Show full text]
  • Petroleum Production and Exploration
    To my family List of Papers This thesis is based on the following papers, which are referred to in the text by their Roman numerals. I Jakobsson, K., Söderbergh, B., Höök, M., Aleklett, K. (2009) How reasonable are oil production scenarios from public agen- cies? Energy Policy, 37(11):4809-4818 II Jakobsson, K., Bentley, R., Söderbergh, B., Aleklett, K. (2011) The end of cheap oil. Bottom-up economic and geologic model- ing of aggregate oil production curves. Energy Policy, in press III Jakobsson, K., Söderbergh, B., Snowden, S., Aleklett, K. (2011) Bottom-up modeling of oil production. Review and sensitivity analysis. Manuscript. IV Jakobsson, K., Söderbergh, B., Snowden, S., Li, C.-Z., Aleklett, K. (2011) Oil exploration and perceptions of scarcity. The falla- cy of early success. Energy Economics, in press V Söderbergh, B., Jakobsson, K., Aleklett, K. (2009) European energy security. The future of Norwegian natural gas produc- tion. Energy Policy, 37(12):5037-5055 VI Söderbergh, B., Jakobsson, K., Aleklett, K. (2010) European energy security. An analysis of future Russian natural gas pro- duction and exports. Energy Policy, 38(12):7827-7843 VII Höök, M., Söderbergh, B., Jakobsson, K., Aleklett, K. (2009) The evolution of giant oil field production behavior. Natural Resources Research, 18(1):39-56 Reprints were made with permission from the respective publishers. The author’s contribution to the papers: Papers I-IV: principal authorship and major contribution to model- ing Papers V and VI: contribution to modeling Paper VII: minor contribution to modeling Complementary paper not included in the thesis: Aleklett, K., Höök, M., Jakobsson, K., Lardelli, M., Snowden, S., Söder- bergh, B.
    [Show full text]